Presentation is loading. Please wait.

Presentation is loading. Please wait.

Three-dimensional MHD simulation of a flux rope driven CME Manchester IV, W.B., Gombosi, T.I., Roussev, I., De Zeeuw, D.L., Sokolov, I.V., Powell, K.G.,

Published byDarleen Johns Modified over 9 years ago

Similar presentations

Presentation on theme: "Three-dimensional MHD simulation of a flux rope driven CME Manchester IV, W.B., Gombosi, T.I., Roussev, I., De Zeeuw, D.L., Sokolov, I.V., Powell, K.G.,"— Presentation transcript:

1 Three-dimensional MHD simulation of a flux rope driven CME Manchester IV, W.B., Gombosi, T.I., Roussev, I., De Zeeuw, D.L., Sokolov, I.V., Powell, K.G., Toth, G., and Opher M. Journal of Geophysical Research, 2004, 109, A01102 2004 May 12 Plasma Seminar Daikou Shiota

2 1. Introduction Coronal Mass Ejection (CME) traditionally defined as large-scale expulsion of plasma typically mass10 15-16 g energy10 31-32 erg LASCO/SOHO

3 Introduction The majority of CMEs originate from the disruption of large-scale coronal structure (helmet streamer) (Hundhausen 1988, 1993) A helmet streamer possesses a three-part structure (a high- density shell, a low density cavity, and a filament) → three-part structure of CMEs It is believed that the breakup of helmet streamers may result from a loss of equilibrium foollowing a slow, nearly quasi-static evolution.

4 Introduction Helmet streamer ・ closed bipolar configuration ・・・ X-ray arcade ・ magnetic shear ・・・ X-ray sigmoid The magnetic configuration of pre-event streamers possibly containing a flux rope coinciding with the plasma cavity (Low 1994, Low and Hundhausen 1995) CMEs are the result of a global MHD process and represent a significant restructuring of the global coronal magnetic field. (Low 1996)

5 CME models sheared magnetic arcade Wolfson (1982), Mikic et al. (1988), Steinolfson (1991), Choe & Lee (1996), Mikic & Linker (1994), Linker & Mikic (1994) magnetic flux ropes Mouschovias & Poland (1978), Chen (1996), Wu & Guo (1997), Wu et al. (1999), Wu et al. (2000) reconnection-driven CME model Forbes & Priest (1995), Lin & Forbes (2000), Chen & Shibata (2000) Antiochos et al. (1999) Introduction

6 Recent 3D model Gibson & Low (1998) analytic description of expansion of a flux rope Amari et al. (2000) formation of a flux rope within an arcade and its subsequent eruption Tokman & Bellan (2002) Introduction

7 In this paper numerically forming a steady-state model ofthe corona along with a bimodal solar wind they superimpose a 3-D magnetic flux rope with in the streamer belt (the solution of Gibson & Low 1998) time evolution

8 MHD model the block-adaptive tree solar wind Roe-type upwind scheme (BATS-R-US) code (Powell et al. 1999, Groth et al 2000) MHD equations

9 Steady-state solar wind model (Groth et al. 2000) bimodal solar wind model Volumetric heating

10 Flux Rope of Gibson & Low (GL) Roussev et al. (2003a) Gibson & Low (1998) self-similar flux rope Force-free solution

11 Flux rope GL type flux rope is superimposed to the steady-state solar wind solution

12 Flux rope plasma β |B| density

13 3D view of the CME |V|

14 Time evolution |V| velocity distribution in the meridional plane

15 Time evolution |V| velocity distribution in the equatorial plane

16 Time evolution and energetics velocity The CME is launched by initial force imbalance. During the first hour the net change The total energy increase is supplied from the magnetic energy of the flux rope. The mass 1.4×10 16 g of plasma is ultimately accelerated by the CME while the flux rope initially contained ~1×10 15 g.

17 Temperature of the shock behind plasma temperature

18 Deceleration empirical relationship of CME deceleration (Sheeley et al. 1999) The deceleration is too large to be accounted for by ballistic motion in the Sun’s gravitational field but rather due to the mass of plasma swept up

19 Synthetic Thomson scattered images X X Z YY Z

20 Summary The authors investigated the time evolution of 3D MHD model of a CME driven by magnetic pressure and buoyancy of a flux rope in an initial state of force imbalance. The model eruption possesses many features associated fast CME. ① the preevent structure is a dense helmet streamer with three-part structure. ② the energy for the eruption comes from preevent magnetic configuration and yields ~5×10 31 erg of kinetic and gravitational energy to drive ~10 16 g of plasma from the corona. ③ the shock in front of the flux rope interacts with the bimodal solar wind. ④ synthetic Thomson-scattered images show density structures that qualitatively represent a loop-cavity structure.

Download ppt "Three-dimensional MHD simulation of a flux rope driven CME Manchester IV, W.B., Gombosi, T.I., Roussev, I., De Zeeuw, D.L., Sokolov, I.V., Powell, K.G.,"

Similar presentations

Observational evidence of a magnetic flux rope eruption associated with the X3 flare on 2002 July 15 Liu Yu Solar Seminar, 2003 June 16.

Observational evidence of a magnetic flux rope eruption associated with the X3 flare on 2002 July 15 Liu Yu Solar Seminar, 2003 June 16.
Lecture 9 Prominences and Filaments Filaments are formed in magnetic loops that hold relatively cool, dense gas suspended above the surface of the Sun,

Lecture 9 Prominences and Filaments Filaments are formed in magnetic loops that hold relatively cool, dense gas suspended above the surface of the Sun,"
Observations on Current Sheet and Magnetic Reconnection in Solar Flares Haimin Wang and Jiong Qiu BBSO/NJIT.

Observations on Current Sheet and Magnetic Reconnection in Solar Flares Haimin Wang and Jiong Qiu BBSO/NJIT.
The magnetic nature of solar flares Paper by E.R. Priest & T.G. Forbes Review presented by Hui Song.

The magnetic nature of solar flares Paper by E.R. Priest & T.G. Forbes Review presented by Hui Song.
The Relationship Between CMEs and Post-eruption Arcades Peter T. Gallagher, Chia-Hsien Lin, Claire Raftery, Ryan O. Milligan.

The Relationship Between CMEs and Post-eruption Arcades Peter T. Gallagher, Chia-Hsien Lin, Claire Raftery, Ryan O. Milligan.
TRACE and RHESSI observations of the failed eruption of the magnetic flux rope Tomasz Mrozek Astronomical Institute University of Wrocław.

TRACE and RHESSI observations of the failed eruption of the magnetic flux rope Tomasz Mrozek Astronomical Institute University of Wrocław.
Lecture 4 The Formation and Evolution of CMEs. Coronal Mass Ejections (CMEs) Appear as loop like features that breakup helmet streamers in the corona.

Lecture 4 The Formation and Evolution of CMEs. Coronal Mass Ejections (CMEs) Appear as loop like features that breakup helmet streamers in the corona.
Sarah Gibson October 2005 Twisted magnetic flux ropes: A breeding ground for CMEs? Sarah Gibson Collaborators: Yuhong Fan, Joan Burkepile, Giuliana de.

Sarah Gibson October 2005 Twisted magnetic flux ropes: A breeding ground for CMEs? Sarah Gibson Collaborators: Yuhong Fan, Joan Burkepile, Giuliana de.
CME/Flare Mechanisms Solar “minimum” event this January For use to VSE must be able to predict CME/flare Spiro K. Antiochos Naval Research Laboratory.

CME/Flare Mechanisms Solar “minimum” event this January For use to VSE must be able to predict CME/flare Spiro K. Antiochos Naval Research Laboratory.
MHD modeling of coronal disturbances related to CME lift-off J. Pomoell 1, R. Vainio 1, S. Pohjolainen 2 1 Department of Physics, University of Helsinki.

MHD modeling of coronal disturbances related to CME lift-off J. Pomoell 1, R. Vainio 1, S. Pohjolainen 2 1 Department of Physics, University of Helsinki.
Magnetic Reconnection Across the HCS Mark Moldwin UM and Megan Cartwright UC-Berkeley Isradynamics April 2010 With thanks to Mark Linton at NRL Linton.

Magnetic Reconnection Across the HCS Mark Moldwin UM and Megan Cartwright UC-Berkeley Isradynamics April 2010 With thanks to Mark Linton at NRL Linton.
Observations –Morphology –Quantitative properties Underlying Physics –Aly-Sturrock limit Present Theories/Models Coronal Mass Ejections (CME) S. K. Antiochos,

Observations –Morphology –Quantitative properties Underlying Physics –Aly-Sturrock limit Present Theories/Models Coronal Mass Ejections (CME) S. K. Antiochos,
A full view of EIT waves Chen, P.F., Fang, C. & Shibata, K. ApJ, 2005, 622, 1202-1210 Solar seminar 2005.6.20 Shiota.

A full view of EIT waves Chen, P.F., Fang, C. & Shibata, K. ApJ, 2005, 622, Solar seminar Shiota.
1 Diagnostics of Solar Wind Processes Using the Total Perpendicular Pressure Lan Jian, C. T. Russell, and J. T. Gosling How does the magnetic structure.

1 Diagnostics of Solar Wind Processes Using the Total Perpendicular Pressure Lan Jian, C. T. Russell, and J. T. Gosling How does the magnetic structure.
STEREO AND SPACE WEATHER Variable conditions in space that can have adverse effects on human life and society Space Weather: Variable conditions in space.

STEREO AND SPACE WEATHER Variable conditions in space that can have adverse effects on human life and society Space Weather: Variable conditions in space.
Chip Manchester, Fang Fang, Bill Abbett, Bart van der Holst Patterns of Large- Scale Flux Emegence Patterns of Large- Scale Flux Emegence.

Chip Manchester, Fang Fang, Bill Abbett, Bart van der Holst Patterns of Large- Scale Flux Emegence Patterns of Large- Scale Flux Emegence.
Simulation of Flux Emergence from the Convection Zone Fang Fang 1, Ward Manchester IV 1, William Abbett 2 and Bart van der Holst 1 1 Department of Atmospheric,

Simulation of Flux Emergence from the Convection Zone Fang Fang 1, Ward Manchester IV 1, William Abbett 2 and Bart van der Holst 1 1 Department of Atmospheric,
What can helicity redistribution in solar eruptions tell us about reconnection in these events? by Brian Welsch, JSPS Fellow (Short-Term ), Space Sciences.

What can helicity redistribution in solar eruptions tell us about reconnection in these events? by Brian Welsch, JSPS Fellow (Short-Term ), Space Sciences.
Chip Manchester 1, Fang Fang 1, Bart van der Holst 1, Bill Abbett 2 (1)University of Michigan (2)University of California Berkeley Study of Flux Emergence:

Chip Manchester 1, Fang Fang 1, Bart van der Holst 1, Bill Abbett 2 (1)University of Michigan (2)University of California Berkeley Study of Flux Emergence:
Two energy release processes for CMEs: MHD catastrophe and magnetic reconnection Yao CHEN Department of Space Science and Applied Physics Shandong University.

Two energy release processes for CMEs: MHD catastrophe and magnetic reconnection Yao CHEN Department of Space Science and Applied Physics Shandong University.

Similar presentations

Ads by Google